Rotating harmonic rejection mixer

ABSTRACT

In one embodiment, the present invention includes a mixer circuit to receive and generate a mixed signal from a radio frequency (RF) signal and a master clock signal, a switch stage coupled to an output of the mixer circuit to rotatingly switch the mixed signal to multiple gain stages coupled to the switch stage, and a combiner to combine an output of the gain stages.

This application is a continuation-in-part of U.S. patent application Ser. No. 12/794,113, filed on Jun. 4, 2010 now U.S. Pat. No. 8,320,863, which is a divisional of U.S. patent application Ser. No. 11/824,417, filed on Jun. 29, 2007, now U.S. Pat. No. 7,756,504, issued Jul. 13, 2010, the contents of which are hereby incorporated by reference.

FIELD OF THE INVENTION

Embodiments of the present invention relate to a mixer and more particularly to a mixer to perform harmonic rejection.

BACKGROUND

A conventional receiver may include at least one mixer to downconvert the frequency of an incoming signal. More specifically, the mixer typically multiplies the incoming wireless signal with a local oscillator signal to produce a signal that has spectral energy that is distributed at sums and differences of the local oscillator and incoming signal's frequencies. For a downconversion mixer, the desired output is the difference between the local oscillator and incoming signal frequency. If the local oscillator signal is a pure sinusoid only the spectral energy of the incoming signal that is at an intermediate frequency (IF) away from the local oscillator (LO) signal appears at the output of the downconversion mixer. However, for certain mixing applications, the local oscillator signal may be a non-sinusoidal, such as a square wave signal, which contains spectral energy that is located at a fundamental frequency and additional spectral energy that is located at harmonic frequencies of the fundamental frequency. Mixing the incoming signal with such a local oscillator signal causes the spectral energy of the incoming signal at IF away from the harmonics of the LO signal to also appear along with the desired signal at the downconversion mixer's output.

Harmonic rejection mixers exist that include multiple mixers such as Gilbert cell type mixers to each receive a scaled version of an incoming signal, where the outputs of each mixer stage are summed to provide a downconverted (or upconverted) output. Each mixer may operate at a phase difference from the other mixers, and each scaling factor that scales the incoming signal may be in accordance with a predetermined sinusoidal function such that the harmonic rejection mixer ideally rejects all harmonics except M×N+/−1, where M is any integer and N is the number of individual mixer stages. However, actual implementations do not operate according to this ideal. Instead, in practical implementations in a semiconductor integrated circuit (IC) process, various problems exist. These problems include difficulties in device matching among the different mixers, as random device mismatches between active devices, i.e., transistors in the mixers may cause the scaling factors to deviate from an ideal value, causing degradation in harmonic rejection. Furthermore, the phases of a LO signal provided to each branch may also deviate, causing harmonic rejection degradation.

To overcome such problems in conventional harmonic rejection mixers, very large device sizes are needed, which creates circuits that are very large and consume significant power. Furthermore, even if a large size is implemented such that the standard deviation of random mismatches is reduced (in turn raising power and area by a factor of 4), harmonic rejection can still be affected by the duty cycle of each LO waveform. Accordingly, positive and negative LO signals should be exactly 180 degrees out of phase, requiring additional well-matched components and operation at higher frequencies, again causing more consumption of power to achieve a desired performance level. In many designs, the amount of harmonic rejection that can realistically be achieved in such a mixer may be between approximately 30-40 dB, when operating at an LO frequency of several hundred MHz. Such performance may be acceptable for some applications. However, operation at this level can cause stricter tolerances for other components in a total budget for a given receiver design.

Thus, there exists a continuing need for a mixer that rejects harmonic frequencies that may be introduced by a local oscillator signal that is not a pure sinusoid.

SUMMARY OF THE INVENTION

In one aspect, the present invention is directed to a mixer that includes a mixer circuit to receive and generate a mixed signal from a radio frequency (RF) signal and a master clock signal, a switch stage coupled to an output of the mixer circuit to rotatingly switch the mixed signal to multiple gain stages coupled to the switch stage, and a combiner to combine an output of the gain stages. In some implementations, the mixer may be a quadrature mixer having in-phase and quadrature portions, and the gain stages may be weighted according to predetermined values, and outputs of the gain stages can be added together to obtain a mixed signal. By using such a mixer, harmonic rejection may be reduced or prevented, in some embodiments.

Yet another aspect of the present invention is directed to a method for operating a harmonic rejection mixer. The method may include receiving an RF signal and mixing the RF signal with a master clock to obtain a mixed signal, cyclically rotating the mixed signal to each of N gain stages for at least one cycle of the master clock (which may occur during a cycle of a LO), and summing the outputs of the N gain stages to provide an output signal. The cyclical rotation of the mixed signal from a first one to a second one of the gain stages may occur, for example, when the master clock is at a low value, and may further occur such that each of the gain stages is to receive the mixed signal for a portion of the LO cycle. In some implementations, the rotation may occur to less than all of the gain stages, based at least in part on a frequency of the RF signal.

Yet another aspect of the present invention is directed to an apparatus that includes a master RF device to receive an incoming RF signal and provide an RF current, where the master RF device includes at least one transconductor. The apparatus may further include a master LO device coupled to an output of the master RF device, where the master LO device receives the RF current and mixes it with a master clock signal to obtain a mixed signal, and a rotating switch device coupled to the master LO device to cyclically switch the mixed signal to one of multiple output ports of the rotating switch device. Coupled to these output ports are corresponding mixer loads to perform gaining and filtering of the mixed signal, and multiple gain stages each coupled to one of the mixer loads to weight the output of the corresponding mixer load and provide an output to a summer. In various implementations, the gain stages include matched passive components and unmatched active components, while the master LO device includes unmatched active components.

Yet another aspect of the present invention is directed to a system that includes a low noise amplifier (LNA) to receive an RF signal, a voltage controlled oscillator (VCO) to generate a VCO frequency, a frequency divider to divide the VCO frequency to obtain a master clock signal, a mixer coupled to an output of the LNA to mix the RF signal with the master clock signal to obtain a mixed signal, and a switch coupled to an output of the mixer to switch the mixed signal to a plurality of gain stages. In one embodiment, the system may further include a summer to combine outputs of the gain stages, a low pass filter (LPF) coupled to an output of the summer, an analog-to-digital converter (ADC) coupled to an output of the LPF; and a demodulator coupled to an output of the ADC.

A still further aspect of the present invention is directed to a method for receiving a request for a channel at a first frequency, determining a number of stages to be enabled in a mixer based at least in part on the first frequency, selecting a master clock frequency corresponding to a multiplied version of a local oscillator (LO) frequency, providing the master clock frequency to a mixer, and mixing an RF signal that includes the channel with the master clock frequency and providing a mixed signal to each of the enabled stages individually for a portion of each LO cycle. The number of enabled stages may be less than all available stages if the channel is in a band less than a predetermined frequency. Note than when a request for a second channel at a second frequency is received, the number of stages to be enabled may be updated based on the second frequency.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a high level block diagram of a mixer in accordance with an embodiment of the present invention.

FIG. 2 is a block diagram of an implementation of a mixer in accordance with one embodiment of the present invention.

FIG. 3 is a schematic diagram of a rotating switch in accordance with an embodiment of the present invention.

FIG. 4 is a timing diagram of control signals for a rotating switch in accordance with one embodiment of the present invention.

FIG. 5 is a timing diagram of complementary control signals for a rotating switch in accordance with one embodiment of the present invention.

FIG. 6 is an example implementation of a gain stage of an intermediate frequency section in accordance with an embodiment of the present invention.

FIG. 7 is a schematic diagram of a quadrature mixer in accordance with an embodiment of the present invention.

FIG. 8 is a block diagram of a portion of a rotating harmonic rejection mixer in accordance with an embodiment of the present invention.

FIG. 9 is a timing diagram of an IF current of a single IF stage in accordance with one embodiment of the present invention.

FIG. 10 is the timing diagram of FIG. 9 in the presence of mismatches in accordance with an embodiment of the present invention.

FIG. 11 is a timing diagram of an IF current of a single IF stage in the presence of noise in accordance with an embodiment of the present invention.

FIG. 12 is a block diagram of a system in accordance with one embodiment of the present invention.

FIG. 13 is a flow diagram of a method in accordance with an embodiment of the present invention.

FIG. 14 is a block diagram of an implementation of a mixer for operation at a UHF band in accordance with one embodiment of the present invention.

FIG. 15 is a timing diagram of control signals for a rotating switch in accordance with another embodiment of the present invention.

FIG. 16 is a timing diagram of complementary control signals for a rotating switch in accordance with this embodiment of the present invention.

DETAILED DESCRIPTION

In various embodiments, a rotating harmonic rejection mixer may be provided to enable improved harmonic rejection for a mixing operation between an incoming radio frequency (RF) signal and a clock frequency signal, such as a master clock which may be a square wave signal whose frequency is a multiplied version of a local oscillator (LO) frequency. In various embodiments, the rotating harmonic rejection mixer may be controlled to enable some or all of a plurality of gain stages of an intermediate frequency (IF), which are then summed to provide an output IF signal for further processing in a given receiver. As used herein, the term “rotating” means that an output of a mixing operation is cyclically rotated to different IF gain stages during a given time period.

Due to the design of the mixer in which the incoming RF signal is downmixed, e.g., to an IF frequency, after which this IF signal is processed by way of gaining, filtering and so forth, any mismatch-causing devices do not operate at high frequencies. Accordingly, better matching passive components may be used and feedback around active devices is also implemented to improve harmonic rejection at significantly lower power and area consumption. Furthermore, in various implementations a mixer may include a single RF device, e.g., a single differential transconductor controlled by a single switching pair. Because there is only a single RF device, no mismatches occur in the RF section.

Furthermore, these front-end devices, i.e., in the RF portion and a local oscillator path, can be formed of minimal-sized devices leading to improved power and area reductions. Also, by using such smaller size devices, bandwidth of a front-end amplifier that provides signals to the mixer, such as a low noise amplifier (LNA) may be increased, as mixer input capacitance can be significantly reduced. In this way, LNA power dissipation may be reduced while providing more flexibility for selection and design of an LNA. In some implementations, resistor areas in an IF section may be optimized such that resistors implementing the peak of a sine wave implementing the phases of the individual IF portions can be wider than those at the rising portion of the sine wave.

While the scope of the present invention is not limited in this regard, such a mixer may be incorporated into various receivers such as a television receiver, radio receiver or other receiver of incoming RF signals. Because the number of such gain stages can be dynamically controlled, embodiments may provide for control of an amount of harmonic rejection to be provided, which may vary given a frequency at which the incoming signals are received. For example, in the context of a television receiver, incoming signals may be received via broadcast of over-the-air signals at VHF or UHF frequencies or via broadband cable at a higher frequency. Depending upon the frequency at which the tuner operates, differing amounts of gain stages may be provided to enable a controllable amount of harmonic rejection to be realized, while also preventing flicker noise in the mixer. Furthermore, by reducing the number of gain stages enabled during operation at certain frequencies, reduced power consumption may be realized.

Referring now to FIG. 1, shown is a block diagram of a mixer system in accordance with an embodiment of the present invention. As shown in FIG. 1, mixer system 10 is coupled to receive an incoming RF signal at a mixer 20, which mixes the incoming signal with a master clock signal. The master clock may be at a frequency of N×LO, where N is an integer corresponding to a number of gain stages (discussed below) in mixer system 10 and LO is at an output frequency of an LO (not shown in FIG. 1). In various embodiments, the LO may include a voltage controlled oscillator (VCO) that generates a sine wave, that in turn may be modified into a square wave signal (e.g., via a frequency divider) along an LO path such that the master clock provided to mixer 20 is a square wave signal. Mixer 20 may thus multiply the incoming RF signal by the master clock and the result is then rotated between a plurality of individual gain stages 30 ₀-30 _(N−1) (generically gain stage 30). As will be described further below, each gain stage 30 has a different gain factor a₀-a_(N−1) associated therewith.

A switch 25 may be controlled to cyclically rotate the output from mixer 20 to each of gain stages 30. The angular velocity of rotation sets the effective LO frequency. For example, if switch 25 has completed one rotation in N cycles of the master clock, the effective LO equals the master clock frequency divided by N. In various implementations, switch 25 may be controlled to be connected to a given gain stage 30 when the LO is at a high value (i.e., when there is a signal through switch 25). When there is no signal through switch 25 (i.e., when the LO is at a low state), it may be rotated to the next gain stage 30. In this way, switch 25 does not contribute any noise, and any offsets within operation of switch 25 do not contribute to any harmonic rejection degradation.

Referring still to FIG. 1, each gain stage 30 has an input IF port (IF₀-IF_(N−1)) that is coupled to receive the output from mixer 20 when switch 25 enables interconnection to the given IF port. Each gain stage 30 scales signal at the IF ports (IF0 to IFn−1) by a different factor, or degree, to produce a resultant signal that is provided to a summer block 40 that combines the outputs of all such gain stages 30 to generate an IF output which may be provided to further circuitry of a tuner to process the received signal. Note that in FIG. 1, IF filters, which may be also referred to herein as mixer loads, that are present on each of the IF ports to enable gaining, filtering and conversion of current to voltage, and coupled between switch 25 and a corresponding gain stage, are not shown for ease of illustration.

Each gain stage 30 may have a different coefficient a_(O)-a_(N−1) that may be selected to cancel harmonics in the incoming signal. More specifically, in some embodiments the a_(k) coefficients where k equals zero to N−1 may be selected based on the following periodic function of the square wave phase:

$\begin{matrix} {a_{k} = {{\sin\left( {\frac{2\pi}{N}k} \right)}.}} & \lbrack 1\rbrack \end{matrix}$

By selecting a given value of N, the harmonics that are cancelled by mixer system 10 may be controlled. As described above, the summation of all of the individual gain blocks 30 (i.e., phases) may be summed at summer block 40 and provided to additional receiver circuitry.

Implementations of a mixer to enable controllable harmonic rejection as well as noise immunity may take different forms. Referring now to FIG. 2, shown is a block diagram of an implementation of a mixer in accordance with one embodiment of the present invention. As shown in FIG. 2, mixer 100 is one example implementation in which an incoming RF signal having positive and negative components RF_(N) and RF_(P) are provided to master RF devices 102. As shown in FIG. 2, master RF devices 102 may include n-channel metal oxide semiconductor field effect transistors (nMOSFETs) 105 and 106 which act as transconductors having gate terminals connected to RF signals RF_(P) and RF_(N), respectively, and providing an RF current through a drain terminal. Thus only a single differential transconductor is present, avoiding any mismatch.

The outputs of master RF devices 102 are provided to master LO devices 110. Master LO devices 110 may act to mix the incoming RF signal with the master clock frequency. Specifically, as shown in FIG. 2 master LO devices 110 may include a plurality of nMOSFETs 112-118 having source terminals coupled to receive an RF output from master RF devices 102 and gate terminals coupled to receive the master clock signal (respectively N×LO_(P) and N×LO_(N)) and having drain terminals to provide an IF output to a plurality of rotating switches 120-126 (generically rotating switch 120). Rotating switches 120 may be controlled by control signals, LO_(a+b)<N−1:0> (note LO_(a) and LO_(b) are distinct signals) respectively, to cyclically switch the output from the master clock devices to each of a plurality of IF output ports, IF<N−1:0>, that in turn are provided to a plurality of IF input ports (e.g., IF_(N−1)-IF₀) of a plurality of mixer loads 130-136 (generically mixer load 130).

Note that the rotating switches in the mixer processing the negative RF signal, namely RF_(n), are connected differently to the IF ports, IF₀ to IF_(n−1). Since RF_(n) is 180 degrees phase shifted with respect its counterpart, RF_(p), the rotating switches' outputs should also be phase shifted by 180 degrees. Since a rotation through N stages implies a phase shift of 360 degrees, a phase shift of 180 degrees is obtained by cyclically shifting through N/2 stages. Thus if a rotating switch in the mixer processing RF_(p) was connected to the IF port, IF_(k), then the corresponding rotating switch in the mixer processing RF_(n) would be connected to IF port IF(_(k+N/2)) or IF_((k−N/2)) depending on whether k was lesser than N/2 or not, respectively (thus the arrayed output of the rotating switches connected to mixer processing RF_(n) is represented in FIG. 2 as IF<N/2−1:0>, (followed by), IF<N−1,N/2> whereas the arrayed output of the rotating switches connected to mixer processing RFp is represented as IF<N−1,0>.) Mixer loads 130 may perform gaining and filtering of the IF signals, and may be RC filters in some embodiments. In some implementations, each such mixer load 130 may have the same RC weighting. The output of the respective mixer loads 130 may be provided through additional gain stages that may include buffers and impedances, and then on to summing blocks (not shown in FIG. 2), which sum the respective phases and provide the IF output to a desired location.

Rotating switches such as switches 120 shown in FIG. 2 can be implemented in a variety of manners. Referring now to FIG. 3, shown is a schematic diagram of an example implementation for a rotating switch in accordance with an embodiment of the present invention. As shown in FIG. 3, rotating switch 120 may include a plurality of nMOSFETS 121 _(N)-121 ₀ (generically MOSFET 121). As shown, each MOSFET 121 has a source terminal coupled to receive a current input from a master LO device 110. Further, each MOSFET 121 may have a gate terminal controlled by a different one of a plurality of control signals LO<0:N−1>. As described above, each MOSFET 121 may be cyclically controlled to enable each MOSFET 121 to output via its drain terminal the current input signal for a given portion of the LO cycle. Thus the outputs of rotating switch 120 may be provided at a plurality of output IF ports IF<0:N−1> that in turn couple to corresponding IF input ports of, e.g., mixer loads 130 of FIG. 2.

To enable rotating switch 120 to rotate the input current between its various outputs, the gates of MOSFETs 121 may be driven in accordance with the timing diagram shown in FIG. 4, in one embodiment. FIG. 4 shows the master clock frequency for the positive input current (i.e., N×LO_(P)) which is a square wave signal. As shown in FIG. 4, for a given period of the LO, N cycles of the master clock may be generated. In turn, each MOSFET of the rotating switches may be controlled cyclically by a given control signal LO_(a)<N−1:0>. Note that these control signals are also square wave signals that may have a pulse width equal to about a time period of the master clock. Furthermore, note that the control signals are individually enabled to a high state during a low portion of the master clock. While shown as switching at approximately halfway through a low state of the master clock frequency, the scope of the present invention is not limited in this regard. By enabling each MOSFET in turn, during a single period of the LO each MOSFET may be enabled for a time period of LO divided by N.

As shown in FIG. 5, a similar timing mechanism may be enabled for the negative master clock signals, i.e., N×LO_(N). Note that the positive and negative master clock frequencies are complementary versions of each other. The transitions in the control signals LO_(a)<K> and LO_(b)<K>, where K equals 0 to N−1 occur when the master clock is at a low state. Thus there is no current in the rotating switches when the gates of the MOSFETs are being toggled, and any random offsets between the MOSFETs in the rotating switches do not affect their output. Note that the same is true for any noise in the switches. Still further, when the master clock is at a high level, the MOSFETs of the rotating switches simply act as cascodes and thus their noise is not important. As a result, any mismatches in the master LO devices affect all outputs of the rotating switches equally. Still further, any mismatches in the master RF devices affect all outputs of the rotating switches equally, because it is the same RF current that is cyclically rotated between the different mixer outputs. Accordingly, mismatches in both the RF and LO devices do not cause any harmonic rejection degradation. Instead, the only components that could cause such harmonic rejection degradation are devices in the IF portions (i.e., mixer loads 130 of FIG. 2). For a downconversion mixer such as used in various receiver architectures, because the IF is at a much lower frequency than the received RF signal, negative feedback stages may be provided and any gain/phase errors caused by these stages are largely dependent on passive components such as resistors and capacitors, and not active components such as transistors. Because for a typical IC process such as a CMOS process, passive components match much better than their active counterparts, enabling mismatch errors between passive components can greatly reduce harmonic rejection degradation.

A mixer in accordance with an embodiment of the present invention thus shifts the device matching problem of harmonic rejection from high frequency RF/LO devices to lower frequency IF devices, and further shifts device matching issues from poorly matching active devices to better matching passive devices. Such a mixer can achieve improved harmonic rejection while reducing both power consumption and die area consumed by the mixer.

As described above, in some embodiments mixer loads 130 of FIG. 2 may be implemented as RC filters. Referring now to FIG. 6, shown is an example implementation of a gain stage of an IF section in accordance with an embodiment of the present invention. As shown in FIG. 6, IF section 200 includes a plurality of IF input ports, IF<N−1>-IF<0>, to receive the output of the master RF and LO devices and mixer loads of FIG. 2 (generically 202). Each input port is coupled to a respective unity gain buffer 210 _(N−1)-210 ₀. While the scope of the present invention is not limited in this regard, in one embodiment a unity gain buffer may be implemented with a pair of MOSFETs, namely a pMOSFET coupled to receive incoming voltage at a gate terminal and having source and drain terminals coupled to different current sources, respectively. In turn, a second MOSFET, which may be a nMOSFET, may have a gate terminal coupled to a drain terminal of the first MOSFET, a source terminal coupled to ground, and a drain terminal coupled to an output terminal (also coupled to the source terminal of the first MOSFET). Such a gain buffer may have a gain set in accordance with the following equation:

$\begin{matrix} {\frac{Vout}{Vin} = \frac{A}{1 + A}} & \lbrack 2\rbrack \end{matrix}$ where A is the open loop gain of unity gain buffer. Note that a large value for A may help reduce mismatch in gains.

Referring still to FIG. 6, unity gain buffers 210 are each coupled to a corresponding resistance 220 _(N−1)-220 ₀. In various embodiments, each resistance 220 may be of a different value. More specifically, in one embodiment:

$\begin{matrix} {{R_{I}\text{<}k\text{>} = \frac{Runit}{\sin\left( {\frac{2\;\pi}{N}k} \right)}\mspace{14mu}{for}\mspace{14mu} k} = {{0\mspace{14mu}{to}\mspace{14mu} N} - 1}} & \lbrack 3\rbrack \end{matrix}$ where Runit is a unitary or normalized resistance value. In some implementations, the unitary resistance value may be based on a resistor ratio such that the different resistors approximate a sine wave as closely as possible to improve harmonic rejection. In some embodiments, the integer ratios may be implemented with resistors connected in parallel for each of R_(I)<k>, with each resistor of a uniform length/width. These resistor ratios may be integer approximations of a sine wave in some embodiments. For example, in one implementation for 16 sine wave coefficients, a plurality of integer values may be chosen to provide for third order harmonic rejection of approximately 56 dB, with fifth order harmonic rejection of approximately 53 dB and seventh order harmonic rejection of approximately 48 db. As shown in Table 1 below, various integer fits for a sine wave may be used in different embodiments, which provide for various levels of harmonic rejection, in one implementation.

TABLE 1 dB dB dB dB Sine wave coefficient (N = 16) S/3 S/5 S/7 S/9 9 17 22 24 22 17 9 0 56 53 48 51 2 12 20 25 26 23 17 8 47 56 42 54 8 17 23 26 25 20 12 2 47 56 52 54 3 13 21 26 27 24 17 8 52 50 48 51 8 17 24 27 26 21 13 3 52 50 48 51 4 14 22 27 28 24 17 7 45 46 51 53 4 15 24 29 30 26 18 8 51 49 48 51 8 18 26 30 29 24 15 4 51 49 49 51

Furthermore, if quarter sine wave coefficients are used, integer ratios of 0, 9^(1/5), 17, 22^(1/5), and 24 may be realized for a quarter sine wave, providing harmonic rejection in excess of 65 dB. By using integers to approximate a sine wave, immunity from end effects and modeling errors may be realized. Note further that the different weighting values used may be applied in different order to the phases than that shown above.

Still referring to FIG. 6, the outputs of each resistance 220 is provided to a differential amplifier 240, which acts to sum all of the signals and provide a differential voltage output I_(output) at a desired IF frequency. Note that feedback resistors, R_(feedback), are coupled between the respective output and input terminals of differential amplifier 240. While shown with this particular implementation in the embodiment of FIG. 6, the scope of the present invention is not limited in this regard. For example, in other implementations rather than the unity gain buffers followed by resistors of FIG. 6, transconductors may be used instead.

FIG. 6 thus shows an implementation that provides a differential IF signal. In other implementations, quadrature signals may be obtained using a different implementation by providing another set of unity gain buffers that in turn are coupled to another set of resistances whose values mimic a “cosine” wave rather than a “sine” wave. In such an implementation, the quadrature phase resistances may be in accordance with the following equation:

$\begin{matrix} {{R_{Q}\text{<}k\text{>}} = {{\frac{Runit}{\cos\left( {\frac{2\;\pi}{N}k} \right)}\mspace{14mu}{for}\mspace{14mu} k} = {{0\mspace{14mu}{to}\mspace{14mu} N} - 1}}} & \lbrack 4\rbrack \end{matrix}$

Referring now to FIG. 7, shown is a schematic diagram of a quadrature mixer in accordance with an embodiment of the present invention. As shown in FIG. 7, mixer 300 may be coupled to receive an incoming RF signal (i.e., RF_(N) and RF_(P)) and positive and negative master clocks (i.e., N×LO_(N) and N×LO_(P)) and mix these signals in a mixer portion 310 which then provides IF outputs to an in-phase IF portion 320 and a quadrature-phase IF portion 330. As described above, in-phase IF portion 320 may include a plurality of unity gain buffers 322 _(N−1)-322 ₀ that in turn are coupled to resistances 324 _(N−1)-324 ₀, outputs of which in turn are provided to a differential amplifier 325. Similarly, quadrature in-phase IF portion 330 may include a plurality of unity gain buffers 332 _(N−1)-332 ₀ that in turn are coupled to resistances 334 _(N−1)-334 ₀, outputs of which are provided to a differential amplifier 335. In this way, mixer 300 provides I and Q IF outputs.

In various embodiments, improved image rejection may be realized in a quadrature mixer. This is so, as matching between I and Q outputs is solely determined by matching in the IF section, for the same reasons discussed above. That is, because mismatches and the master LO devices and master RF devices do not cause any gain/phase errors between the different IF<k> outputs, the quadrature signals derived from these IF outputs have improved image rejection.

In addition to improved harmonic and image rejection provided by embodiments of the present invention, better second-order intermodulation products (IP₂) also can be achieved.

Referring now to FIG. 8, shown is a block diagram showing a portion of a rotating harmonic rejection mixer in accordance with an embodiment of the present invention. Note mixer 100 of FIG. 8 may correspond to the positive portion of mixer 100 shown in FIG. 2. Thus, an incoming RF signal is passed through a transconductor 105, providing positive and negative current portions I_(P) and I_(N) through MOSFETs 112 and 114. In turn, these currents are switched through rotating switches 120 and 122. Only a single one of the switch outputs is shown, namely IF₀, from rotating switches 120 and 122. This current I_(IF)<0> is thus a combination of the individual positive and negative currents from rotating switches 120 and 122.

Referring now to FIG. 9, shown is a time domain analysis of the IF current provided by such a single one of the IF output ports (i.e., I_(IF)<k> for any k), which is a combination of both positive and negative currents provided by master LO devices 112 and 114 for the duration of one N×LO time period. As shown in FIG. 9, both the positive and negative input currents (Ip and In) are square waves that complement each other such that the combined current into any IF port has a pulse width equal to the sum of pulse widths of Ip and In. Thus, the pulse width of the current pulse into any IF port is equal to one period of N×LO clock.

In the presence of mismatches in the active devices, e.g., in the master LO devices, the time domain of FIG. 9 may evolve into the time domain of FIG. 10, in which the dashed lines show the corresponding waveforms in the presence of mismatches in the active components of the master LO devices. Because of the complementary nature of the signals, mismatches in these master LO devices do not change the pulse width of the IF output current, I_(IF)<k> for any k, as shown in FIG. 10. Accordingly, the low frequency IM₂ component appears the same way in each of the IF outputs and is ultimately cancelled in the IF stage as:

$\begin{matrix} {{IF} = {\sum\limits_{K = 0}^{N - 1}{a_{K} \times {IF}\mspace{14mu}\text{<}k\text{>}}}} & \lbrack 5\rbrack \end{matrix}$ where

$a_{K} = {\sin\;\left( \frac{2\pi\; k}{N} \right)}$ for k=0 to N−1, because for every k, a_(K)=−a_(K+N/2). Accordingly, mismatches in the master LO devices do not contribute to IP₂ degradation and instead IP₂ degradation is solely determined by low frequency matching in the IF section, similar to that described above with regard to harmonic rejection degradation.

In addition to mismatches that may exist between the MOSFETs of the master LO devices, flicker noise may also be present. Referring now to FIG. 11, shown is a timing diagram of a current into a given IF port IF<k>, which is obtained by summing the positive and negative currents I_(N) and I_(P). As shown in FIG. 11, the dashed lines indicate current waveforms in the presence of flicker noise in the MOSFETs of the master LO devices. Note that the pulse width of IF<k> and thus the DC component is unaffected by this flicker noise. Accordingly, even in the single-ended outputs of IF<k>, flicker noise of the LO switching devices is absent. Accordingly, there is no need to rely on matching between positive and negative sides to obtain differential low flicker noise.

Still further, embodiments of the present invention provide for lower input referred thermal noise as compared to a conventional square wave mixer. That is, given the same total transconductor current, input referred noise of a mixer in accordance with an embodiment of the present invention may be significantly smaller, for example, on the order of 2(π²/8), as noise downconversions from LO harmonics which may be present in a conventional mixer are absent in embodiments of the present invention.

Embodiments may be implemented in many different system types. As described above, applications may include mixed signal circuits that include both analog and digital circuitry. Referring now to FIG. 12, shown is a block diagram of a system in accordance with one embodiment of the present invention. As shown in FIG. 12, system 1000 may be a television that is coupled to receive a RF signal from an antenna source, cable distribution, or other source. The incoming RF signal may be provided to a television tuner 1005 which may be, in one embodiment a single-chip mixed signal device. Television tuner 1005 may incorporate embodiments of the present invention to provide improved harmonic and image rejection while consuming lower power and area.

Referring still to FIG. 12, tuner 1005 includes a bandpass filter 1110 having an output coupled to a low noise amplifier (LNA) 1115 to receive and amplify the RF signal from an antenna 1001. The output of LNA 1115 is provided to another bandpass filter 1120 that in turn is coupled to mixer 1125, which may be a rotating mixer in accordance with an embodiment of the present invention. As shown in FIG. 12, mixer 1125 receives a master clock signal having a frequency of N×LO from a frequency divider 1135 which in turn is coupled to receive a VCO frequency from a voltage control oscillator (VCO) 1130. While the scope of the present invention is not limited in this regard, the VCO frequency may be at a relatively high frequency, e.g., at least several GHz. In turn, frequency divider 1135 generates a divided frequency that is provided at the master clock value, which may be at a frequency of between approximately 1000 and 2000 MHz. In turn, mixer 1125 downconverts the incoming RF signal with the master clock signal to generate a complex IF output at a frequency of less than approximately 10 MHz. The complex I and Q IF signals output from mixer 1125 are provided to unity gain buffers 1140 a and 1140 b and are filtered by lowpass filters 1145 a and 1145 b and then may be digitized by ADCs 1150 a and 1150 b.

Referring still to FIG. 12, the digitized output of tuner 1005 may be provided to additional processing circuitry within television 1000, such as a demodulator 1170 and associated circuitry to enable a processed television signal to be provided to a display 1175. While shown with this particular implementation in the embodiment of FIG. 12, it is to be understood the scope of the present invention is not limited in this regard. Furthermore, it is to be understood that embodiments may be implemented in many different devices, such as receivers, transmitters and so forth. Still further, control logic, program storage or other computer readable media may be present to store instructions that when executed within a processor of tuner 1000 perform control of a number of gain stages, master clock frequencies, and thus harmonic rejection provided.

Referring now to FIG. 13, shown is a flow diagram of a method in accordance with an embodiment of the present invention. As shown in FIG. 13, method 500 may be used to dynamically adjust a number of gain stages in a mixer. By doing this, reduced power consumption may be realized while achieving a desired level of harmonic rejection, image rejection and so forth for incoming signals of a given frequency. As shown in FIG. 13, method 500 may begin by receiving a request for a channel at a given frequency (block 510). For example, a tuner that is part of a television receiver may receive a request from a user for programming on a certain channel. Based on that frequency, which is at a given frequency based on the band in which the channel is included, the number of stages N to be enabled in a mixer may be determined (block 520). For example, the following table shows the number of stages in the mixer (N) for different input frequency ranges. Having different values of N for different input frequency ranges enables a mixer to reject only desired number of harmonics while saving power in the front end dividers (e.g., 1135 in FIG. 12). The value of N may be controlled by programming of software, e.g., during incorporation of a tuner into a given system.

Input Frequency Range Mixer stages (N)  40 MHz-125 MHz 16 105 MHz-170 MHz 12 155 MHz-255 MHz 8 210 MHz-337 MHz 6

Referring still to FIG. 13, then a master clock frequency may be selected based on this determined number of stages N (block 530). That is, a LO frequency may be provided to a clock multiplier, frequency divider or so forth that generates a master clock frequency of N.LO. This master clock frequency may thus be provided to the rotating mixer (block 540). Using this signal and an incoming RF signal that includes the desired channel, a mixing operation may occur such that a mixed signal corresponding to an IF signal may be switched to each of the N IF stages during each master clock cycle (block 550). The sum of these IF outputs for each clock cycle may be summed and sent along for further processing (block 560). While shown with this particular implementation in the embodiment of FIG. 13, the scope of the present invention is not limited in this regard. As described above, in some embodiments machine-readable instructions may implement the method of FIG. 13.

In further embodiments, in addition to using a rotating harmonic rejection mixer for incoming signals at a VHF band, such an RHRM can further be used for downconversion of incoming signals at a UHF band. To effect this downconversion, a RHRM can be differently configured for use at a UHF frequency. This different configuration can be by an entire separate mixer path for the UHF band that is configured differently. As an example, a given semiconductor-based receiver can include 2 mixer paths, one configured as in, e.g., FIG. 2 and one configured as in FIG. 14, discussed below. As an example the mixer of FIG. 2 can be used for certain frequency bands, e.g., VHF low frequencies, while the mixer of FIG. 14 can be used for other frequency bands, e.g., VHF high frequencies and UHF frequencies. Or in other embodiments, a single mixer path as described above can be configurably controlled to provide a different configuration for operation at a UHF frequency.

Referring now to FIG. 14, shown is a block diagram of an implementation of a mixer for operation at a UHF band. As seen in FIG. 14, mixer 600 may generally correspond to mixer 100 described above with regard to FIG. 2. However, in the embodiment of FIG. 14 the master clock frequency is at a frequency of NLO/2, rather than a value of NLO. Here, N corresponds to the number of IF outputs, namely N mixer loads. As seen, a positive component RF_(P) of an incoming RF signal is coupled to a master RF device 602. For clarity in FIG. 14, only the mixer branch carrying the positive component of the RF current, RF_(P), is shown. Understand that a similar configuration may be present for processing the negative component RF_(N) of the RF current. Master RF device 602 may be an nMOSFET that acts as a transconductor having a gate terminal coupled to receive this RF signal and provide an RF current through its drain terminal. In turn, the output of this master RF device is provided to a pair of master LO devices 610, which may act to mix the incoming RF signal with the master clock frequency of NLO/2. As seen, these master LO devices also may be formed of nMOSFETS. As seen, master LO device 610 _(a) is driven on a rising edge of a master clock signal of a positive polarity (MLO_(P)) and correspondingly, master LO device 610 _(b) is driven by a rising clock edge of a negative polarity master clock signal, namely MLO_(N).

As further seen in FIG. 14, the outputs of the master LO devices, which are IF outputs, are provided to a plurality of rotating switches. Namely, a set of even N/2 rotational switches 620 ₀-620 _(n−2) may be coupled to master LO device 610 _(a) and similarly a set of odd N/2 rotating switches 622 ₁-622 _(n−1) are coupled to the output of master LO device 610 _(b). These rotating switches may be controlled by control signals LO_(a+b)<0:n−1> as shown in FIGS. 15 and 16 to thus cyclically switch the output from the master clock devices to a corresponding one of a plurality of IF output ports that in turn are provided to a plurality of IF input ports of a plurality of mixer loads 630 ₀-630 _(n−1) (generically mixer load 630). Thus in the embodiment of FIG. 14, N rotational switches (N/2 even rotational switches and N/2 odd rotational switches) are each coupled to only a single mixer load 630, and each mixer load 630 only receives an output from one rotational switch. This is in contrast to the implementation of FIG. 2, in which 2N rotational switches are present, with switches from both the positive polarity clock portion and the negative polarity clock portion feeding a given mixer load. Note that the outputs from the mixer loads can be provided to corresponding gain stages and a combiner, as shown above in FIG. 6. Further, a quadrature mixer such as shown in FIG. 7 can be designed using the mixer arrangement of FIG. 14.

By using an implementation such as that of FIG. 14, the same number of multi-phase IF signals can be generated as in the above embodiments using a reduced master clock frequency. As a result, power consumption can be reduced. Furthermore, by use of a lower incoming LO frequency (e.g., 4 GHz) instead of a higher LO frequency (e.g., 8 GHz clock), layout considerations also can be improved. That is, at this lower frequency rather than providing a differential connection between the LO and the mixer, only a single ended connection of the LO signal can be provided, reducing routing and power consumption further. Further for the implementation shown in FIG. 14, in order to reject flicker noise and reduce sensitivity to RF device mismatches, voltage transitions at gates of the rotational switches of the mixer occur within half the time period of the NLO/2 clock compared with NLO clock for the topology shown in FIG. 2. Since the master clock frequency is lower, more time is available for the transitions to happen, which implies that weaker drivers that consume lesser power can be used for driving the gates of the rotational switches. This saves power and simplifies design.

Note that device mismatches may be present, e.g., in the master LO devices. With such mismatches, the even pulses may widen and the odd pulses may narrow. However, with these mismatches the phase differential between adjacent IF stages is unaffected. However the gain to the stages can be affected since gain to an odd IF stage is increased while gain to an even IF stage is decreased. As a result, N/2±1 harmonics can be affected by RF device mismatches and a differential MLO duty cycle that deviates from the ideal 50%. But even in this case, the harmonic rejection obtained at UHF frequencies is sufficient for various implementations. And furthermore, the tradeoff of the lesser harmonic rejection performance is outweighed by the lower power, lower area and simpler design.

Different values of N can be active depending on a frequency of a desired channel. As described above with regard to the method of FIG. 13, based on the band in which the channel is included, the number of stages N to be enabled in a mixer may be determined. The following table shows the number of stages N to be enabled in a UHF portion of a mixer for different input frequency ranges. Having different values of N for different input frequency ranges enables a mixer to reject only desired number of harmonics while saving power in the front end dividers. The value of N may be controlled by programming of software, e.g., during incorporation of a tuner into a given system.

LO Frequency Range Number of Mixer Phases (N) 457 MHz-578 MHz 8 533 MHz-675 MHz 10 640 MHz-810 MHz 12 800 MHz-1012 MHz 14

With regard to flicker noise, with certain values of N (e.g., 10, 14), 1/f noise may not be rejected at the differential IF output (e.g., IF_(k)-IF_(k+n/2)) as if the current to an odd IF stage narrows, the current to the next even IF stage widens. However, for other values of N, the flicker noise can be cancelled as common mode. For example, for N equals 8, 12 the flicker noise is rejected because if K equals odd, then K+N/2 equals odd also and thus the flicker noise cancels as common mode.

For other values of N in which 1/f noise may be present, e.g., N=10, 14, the flicker noise causes less DC voltage at the odd IF stages and more DC voltage at the even IF stages. However, flicker noise can be canceled at the summed output from these stages if

${\sum\limits_{odd}A_{k}} = {{0\mspace{14mu}{and}\mspace{14mu}{even}\;{\sum\limits_{even}A_{k}}} = 0.}$ This equality can be true for equally spaced samples of a sine wave. Accordingly, careful selection of coefficients of the gain stages following the mixer loads can realize flicker noise cancellation for these values of N as well. Referring now to Table 2, shown are representative weights for gain stages for different values of N.

TABLE 2 N  8(I) 0 17 24 17 0 −17 −24 −17  8(Q) 24 17 0 −17 −24 −17 0 17 10(I) 3.75 17 23.75 21.4 10.9 −3.75 −17 −23.75 −21.4 −10.9 10(Q) 23.75 17 3.75 −10.9 −21.4 −23.75 −17 −3.75 10.9 21.4 12(I) 6.2 17 23.2 23.2 17 6.2 −6.2 −17 −23.2 −23.2 −17 −6.2 12(Q) 23.2 17 6.2 −6.2 −17 −23.2 −23.2 −17 −6.2 6.2 17 23.2 14(I) −2.67 7.9 17 22.67 23.83 20.33 12.75 2.67 −7.9 −17 −22.67 −23.83 −20.33 −12.75 14(Q) 23.83 22.67 17 7.9 −2.67 −12.75 −20.33 −23.83 −22.67 −17 −7.9 2.67 12.75 20.33

Note that for a quadrature mixer such as realized using the mixer front end of FIG. 14 and the quadrature backend of FIG. 7, certain considerations can be taken into account when N is not a multiple of four. That is, quadrature signals can be readily realized by performing a phase shift of N/4 when it provides a 90° phase shift. However, for other values of N, e.g., 10 and 14, this shift is not possible.

Instead for other values of N, to obtain coefficients for the gain stages, angles can be chosen symmetrically about a 45° line through a unit circle and furthermore, projections on the X axis can correspond to the in-phase or I coefficients and projections on the Y axis can correspond to the quadrature or Q coefficients. Note that the I and Q coefficients both draw from the same set of numbers, reducing complexity as programmability can be reduced by half, as the I and Q outputs share the same coefficients, as seen above in Table 2. And furthermore, these values can provide for the same harmonic rejection performance on both the I and Q paths.

While the present invention has been described with respect to a limited number of embodiments, those skilled in the art will appreciate numerous modifications and variations therefrom. It is intended that the appended claims cover all such modifications and variations as fall within the true spirit and scope of this present invention. 

What is claimed is:
 1. A mixer comprising: a mixer circuit to receive and generate a mixed signal from an input radio frequency (RF) signal and a master clock signal corresponding to a local oscillator (LO) frequency multiplied by N/2, wherein N corresponds to a number of phases of the mixer; a switch stage having N rotational switches coupled to an output of the mixer circuit, each of the N rotational switches to rotatingly switch the mixed signal to a corresponding one of N gain stages coupled to the switch stage; and a combiner to combine an output of the N gain stages.
 2. The mixer of claim 1, wherein N is controllable based on a frequency of the input RF signal.
 3. The mixer of claim 1, wherein the switch stage is to cyclically rotate the mixed signal to each of the N gain stages during a single cycle of the LO frequency.
 4. The mixer of claim 3, wherein the switch stage is to rotate the mixed signal when there is no signal through the switch stage.
 5. The mixer of claim 1, wherein the mixer comprises a quadrature mixer having an in-phase portion and a quadrature portion.
 6. The mixer of claim 5, wherein the N gain stages are weighted according to a predetermined value, and outputs of the N gain stages are added together.
 7. The mixer of claim 6, wherein an in-phase portion of the gain stages are weighted according to a sampled sine wave and a quadrature phase portion of the gain stages are weighted according to a sampled cosine wave.
 8. The mixer of claim 6, wherein the gain stages are weighted according to coefficients obtained from values symmetric to a non-zero degree line through a unit circle.
 9. The mixer of claim 1, further comprising a plurality of mixer loads coupled between the switch stage and the plurality of gain stages, each of the plurality of mixer loads coupled to receive an intermediate frequency (IF) output from one of the N rotational switches.
 10. A method comprising: receiving an input radio frequency (RF) signal and a master clock signal corresponding to a local oscillator (LO) frequency multiplied by N/2, when a desired channel within the input RF signal is at a first band and generating a mixed signal therefrom, wherein N corresponds to a number of gain stages; rotatingly switching the mixed signal to the N gain stages; and combining an output of the N gain stages.
 11. The method of claim 10, further comprising when the desired channel within the input RF signal is at a second band, generating a second mixed signal from the input RF signal and a second master clock signal corresponding to the local oscillator (LO), rotatingly switching the second mixed signal to the N gain stages, and combining an output of the N gain stages.
 12. The method of claim 10, further comprising: receiving the mixed signal in a switch stage coupled to an output of a mixer circuit that generates the mixed signal; and combining the gain stage outputs in a combiner coupled to the N gain stages.
 13. The method of claim 10, further comprising controlling N based on a type and a frequency of the input RF signal, wherein N corresponds to a number of the plurality of gain stages to be enabled.
 14. A mixer comprising: a mixer circuit to receive and generate a mixed signal from an input radio frequency (RF) signal and a master clock signal corresponding to a local oscillator (LO) frequency multiplied by N/2, the mixer circuit having a single differential transconductor to receive the input RF signal and to output an RF current and master LO devices to mix the RF current with the master clock signal to generate the mixed signal, wherein N corresponds to a number of phases of the mixer circuit; a switch stage having N rotational switches coupled to an output of the mixer circuit, each of the N rotational switches to rotatingly switch the mixed signal to a corresponding one of N gain stages coupled to the switch stage; and a combiner to combine an output of the N gain stages.
 15. The mixer of claim 14, wherein N is controllable based on a frequency of the input RF signal.
 16. The mixer of claim 14, wherein the switch stage is to cyclically rotate the mixed signal to each of the N gain stages during a single cycle of the LO frequency.
 17. The mixer of claim 16, wherein the switch stage is to rotate the mixed signal when there is no signal through the switch stage.
 18. The mixer of claim 14, wherein the mixer comprises a quadrature mixer having an in-phase portion and a quadrature portion.
 19. The mixer of claim 18, wherein the N gain stages are weighted according to a predetermined value, and outputs of the N gain stages are added together. 